Touching microlens structure for a pixel sensor and method of fabrication

ABSTRACT

A structure and method for increasing the sensitivity of pixel sensors by eliminating a gap space formed between adjacent microlens structures in a pixel sensor array. Advantageously, exposure and flowing conditions are such that adjacent microlens structures touch (are webbed) at a horizontal cross-section, yet have a round lens shape in all directions. Particularly, exposure and flowing conditions are such that each touching microlens structure is formed to have a matched uniform radius of curvature at a horizontal cross-section and at a 45 degree cross-sections. To improve quality of mircrolens structure uniformity exhibited at all pixel locations including those near a pixel array edge or corner, a top anti-reflective coating layer is applied on top of a photoresist layer prior to the exposure and flowing steps.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present invention is a continuation-in-part of commonly-owned, co-pending U.S. patent application Ser. No. 10/908,601 filed on May 18, 2005 entitled A TOUCHING MICROLENS STRUCTURE FOR A PIXEL SENSOR AND METHOD OF FABRICATION, the contents and disclosure of which is incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention related generally to the fabrication of semiconductor pixel sensor arrays, and more particularly, to a novel process for forming a microlens structure.

2. Discussion of the Prior Art

CMOS image sensors are beginning to replace conventional CCD sensors for applications requiring image pick-up such as digital cameras, cellular phones, PDA (personal digital assistant), personal computing devices (mobiles, laptops and the like). Advantageously, CMOS image sensors are fabricated by applying present CMOS fabricating process for semiconductor devices such as photodiodes or the like, at low costs. Furthermore, CMOS image sensors can be operated by a single power supply so that the power consumption for that can be restrained lower than that of CCD sensors, and further, CMOS logic circuits and like logic processing devices are easily integrated in the sensor chip and therefore the CMOS image sensors can be miniaturized.

The patent literature is replete with references describing image sensor arrays having a microlens structure and aspects of their manufacture. United States Patent Publication Nos. 2002/0034014, 2004/0099633, 2004/0146807, 2004/0147059 and 2004/0156112 describe state of the art microlens structures and methods of manufacture for image arrays. Basically, the typical method for fabricating a microlens structure comprises: first a layer of photoresist is applied, e.g., by spin coating or like application process (e.g., dip coating, chemical vapor deposition, brushing, evaporation and other like deposition techniques), atop a wafer surface. For instance, as shown in FIG. 1A, the wafer surface may comprise a dielectric planarization layer formed over a substrate 40 that includes an array of color filter structures each associated with an active light sensitive device (e.g., photodiode) of a pixel. It is understood that a positive or negative photoresist may be applied with attendant photolithographic processing steps applied; however, for purposes of discussion, it is assumed a positive photoresist is applied. After a soft bake process, a photoresist mask, such as chrome on glass, is applied having a patterned grid comprising a two-dimensional array of translucent squares or rectangle openings corresponding to the pixel microlens structure to be printed. After aligning the mask to the correct location, the mask and wafer are exposed to a controlled dose of UV light to transfer the mask image. In this example, polymer resist surrounding each exposed square (or rectangular) regions generate acid under uV exposure so that these regions dissolve in a subsequent application of a basic developer chemical. Then, after a post-exposure bake process, a developer step is performed (the kinds of developers that can be employed are well known to those skilled in the art and are dependent on whether a positive or negative photoresist is employed) to remove the soluble areas of the photoresist leaving a visible array pattern of square (or rectangular) shaped islands 42 on the wafer surface separated by thin gaps. Then, as shown in FIG. 1B, after a further blanket expose step, the photoresist pattern is subject to a heating and reflow process to convert the raised photoresist islands into semi-spherical convex lenses 45 of circular plan shape linearly aligned in correspondence with the color filter and active photoelectric converting device.

One problem experienced in the manufacture of pixel microlens structures is that of thin film interference that occurs wherever there is a thin, transparent film. Some light reflects off of the top surface of the photoresist and some light transmits through the photoresist (or any other film for that matter) and reflects off the surface below it. This light then reflects back up, hits the top surface again and either transmits through or reflects back down and interferes constructively or destructively with the light that initially went through. Whether it is destructive or constructive interference depends on whether the light is calumniated (in phase) and, further depends upon the thickness of the layer. If the waves are out of phase they destructively interfere, if they are in phase they constructively interfere. A consequence of either constructive or destructive interference is that it changes the effective dose that is being used during the above-mentioned UV light exposure steps. As shown in FIG. 2A, this is especially apparent at the edges or corner 70 of the metal (MZ) (e.g., aluminum) frame 80 in which a resist layer 64 of thickness “D” used in forming the lens array is formed. As shown in FIG. 2A, when a lens resist is coated (stepped) over the metal frame in the corner of the array, the resist is thicker, as shown as thickness D′, and this changes the thin film interference giving a different dose. The different dose results in the formation of a grossly different lens shape. That is, due to the topography shown as increased thickness D′ at the edge/corner of the array near the metal frame 80, there results little or no process window at the edge of the array (near the frame), and, as shown in FIG. 2B, the formed lenses 95 melt together causing lens variability in size and shape. This is in contrast to the more uniform, correctly-shaped lenses 97 formed further away from the array corners (MZ frame edge) where topographic effects are less an issue.

While it is the case that increased dose and focus centering and dropping the resist thickness assist in countering the small process window phenomenon, the problem is still exacerbated at the array edge/corners, i.e., the MZ fill makes for topography at edge of the frame.

In the manufacture of a pixel sensor array by implementing a process intended to provide touching microlens structures, i.e., a microlens structure having substantially no space between the microlens structure of adjacent pixels to thus maximize light collection, it would be highly desirable to fix the microlens process window to correct for the thin film interference problem exhibited at the corner of the lens array caused by the MZ frame edge topography and not just overexpose to improve the process window but make the gaps between the lens grow.

SUMMARY OF THE INVENTION

The present invention addresses improvements in the manufacture of webbed (i.e., touching) microlens structures for increasing the sensitivity of pixel imaging arrays (e.g., optical image sensors).

According to the present invention, in the formation of webbed microlens structures, additional processing steps are implemented to effectively increase the microlens process window to correct for the thin film interference problem exhibited at and near edges and corners of the lens array caused by a metal (MZ) frame edge topography.

In accordance with the present invention, a Top Anti-Reflective Coating (TARC) layer in conjunction with additional water rinse and dry steps, is provided to eliminate thin film interference phenomena, i.e., increases the process window.

Thus, according to the present invention, there is provided a sensor including an array of pixels, each pixel comprising:

a layer comprising a plurality of microlens structures for receiving light;

a semiconductor substrate including a light sensitive element formed therein for receiving light incident to the pixel and focused by a respective microlens structure; and,

one or more dielectric material and embedded metallization layers provided between the substrate and a top layer,

wherein each microlens structure of a pixel is webbed in a direction such that the structure touches a microlens structure of an adjacent pixel in the array, and such that a curvature of the mircrolens structure is uniform in all directions to thereby maximize collection of light incident to the microlens structure from all directions, the mircrolens structure uniformity exhibited at all pixel locations including those near a pixel array edge or corner.

The touching microlens structure of the invention is such that the gaps between adjacent microlens structures is tailored to achieve a level of horizontal webbing and corner openness such that all light incident to the microlens is optimally captured and focused into the pixel active device area. Thus, the microlens array for the pixel sensor comprises microlens structures that remain connected and perfectly formed, i.e., the 45° degree radius of curvature of the formed lens structure is matched to the cross-section of the formed lens structure thereby maximizing the light collection, even at the reduced pixel sizes.

According to another aspect of the invention, there is provided a method for fabricating a touching microlens structure for a pixel array or sensor. The method comprising the steps of:

-   -   a. providing a substrate including a plurality of light         sensitive elements adapted to receive light incident to a         respective pixel microlens;     -   b. forming a photoresist material layer over the substrate;     -   c. applying an anti-relfective coating layer on top of the         photoresist material layer;     -   d. patterning the photoresist layer using a first sub-resolution         condition to form microlens structure images, the first         sub-resolution condition applied in a manner sufficient to form         partially connected lens portions at gaps between adjacent         microlens structures;     -   e. developing the photoresist layer to partially form the         patterned microlens structures having partially connected lens         portions at the gaps;     -   f. blanket applying a second sub-resolution condition to the         partially formed microlens structures; and,     -   g. flowing the partially formed microlens structures, wherein         each microlens structure is webbed such that the microlens         structure touches a microlens structure of an adjacent pixel in         the array, and such that a curvature of the microlens structure         is uniform in all directions to thereby maximize collection of         light incident to the microlens structure from all directions,         the mircrolens structure uniformity exhibited at all pixel         locations including those near a pixel array edge or corner.

In accordance with this aspect of the invention, a solution is provided whereby the lithographic image in sub-resolution remains connected with a partial opening and when this image is flowed to form a lens, the lenses remain connected and perfectly formed especially near the edges or corners of the array where topographic changes result due to formed metallization (e.g., frame). In addition, it is found that by further underexposing out this image, thin lenses can be made with thick material. Thus, instead of controlling the microlens thickness with resist thickness—which becomes difficult as the lens get thinner as they scale, the thickness is adjusted by the lithographic conditions (sub-threshold exposure, develop, blanket exposure and post expose bake, or develop) and the application of the TARC prior to lens resist patterning. In this manner, a microlens structure is achievable that remains connected and perfectly formed, and beneficially, the 45° degree radius of curvature of the formed lens structure can be matched to the cross-section of the formed lens structure, thereby maximizing the light collection.

Advantageously, according to the methodology of the invention, dimensions of the microlens structure, including lens size, height and radius of curvature can be controlled for webbed microlens designs. Moreover, very thin webbed lens structure can be made with thick resist producing a more focused lens.

BRIEF DESCRIPTION OF THE DRAWINGS

The objects, features and advantages of the present invention will become apparent to one skilled in the art, in view of the following detailed description taken in combination with the attached drawings, in which:

FIGS. 1A and 1B depict pixel sensor arrays formed according to conventional semiconductor manufacturing techniques;

FIG. 2A depicts the increase in thickness of applied lens photoresist at the edge or corner of the metal (MZ) frame 80 when a lens resist is coated (stepped) over the metal frame; and

FIG. 2B depicts the formation of a grossly different lens shape due to the topography change as a result of little or no process window at the edge of the array (near the frame);

FIG. 3A illustrates a method of forming the touching microlens structure according to one embodiment of the invention;

FIG. 3B illustrates a method of forming the touching microlens structure according to an improved process according to the preferred embodiment of the invention;

FIG. 4 depicts a pixel sensor array 10 in which the touching microlens structure of the present invention may be employed;

FIG. 5 illustrates a graph of microlens spacewidth both with the applied TARC (line 95) and without the applied TARC (line 96) (i.e., no thickness) while varying the thickness of the resist layer to simulate the thickness change at the MZ frame in the edge/corners of the array;

FIG. 6 illustrates through a cross-sectional view, an pixel sensor cell 200 formed in accordance with the present invention showing a matched radius of curvature at the webbed (horizontal) cross section as compared to the cross-section at the 45 degree cut;

FIG. 7 shows a graphical depiction of a cross section analysis of an example microlens structure formed according to the method of the invention with a lens width “w” and a height “h” and points depicting the shrinking of the lens at the gaps, with the radius of curvature “R” at the cross-section view depicted; and,

FIG. 8 depicts the resulting improvement in lens uniformity at the MZ frame in the edge/corners of the array of a formed pixel array.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Co-pending U.S. patent application Ser. No. 10/908,601, incorporated by reference herein, describes a system and method for forming webbed (touching) microlens structures in a pixel array optimized for maximizing light transmission therethrough. According to the method 100, as shown in FIG. 3A, the process includes the steps of: applying a photoresist to a wafer or substrate first flowing a patterned photoresist on a smooth planarization layer or equivalent substrate (steps 105, 107), and, exposing the resist material to a partial blanket (sub-threshold) exposure dose using a UV exposure tool (step 110) and developing the resist (step 115). Subsequently, a post exposure bake is performed (step 118). To achieve touching of the microlenses structures, the photoresist pattern is “webbed” before flow. Webbing is achieved by a variety of methods: for instance, by controlling (e.g., reducing) the initial UV exposure dose; set focusing at a non-optimal value; reducing develop time, temperature, or concentration; or, modifying the rate of cross-linking polymers of the resist material when conducting the post exposure bake (step 120). The mask image may additionally be compensated or the wavelength or numerical aperture (NA)/Sigma combination of the lithography tool altered to web the image. After application of one or more of these process modifications, the bottom of the photoresist in the transferred images connects to the bottom of the adjacent gap, i.e., a web is formed. Then, after a subsequent reflow process, the desired lens shape is formed.

As shown with the method 100′ depicted in FIG. 3B, in accordance with the present invention, an additional step 106 is performed that includes the step of applying a Top Anti-Reflective Coating (TARC) layer coating on the whole wafer after the lens apply bake.

A description of the touching microlens process improvement is now described with reference to FIG. 3B. As shown in FIG. 3B, method 100′ comprises the first step 105 representing the step of applying the resist to the wafer surface. The resist material may comprise positive or negative photoresist materials well known in the art; however, preferably, a positive resist is applied (such as an industry standard transparent photoresist, e.g., JSR, MF401H) on to one surface of semiconductor wafer utilizing conventional spinning techniques and conditions. The thickness of the spun down resist may vary depending on the rotational speed of the wafer employed in the spinning process and the type of resist material being spun. Typically, the spinning conditions are such that the resist is spun down to a resist film thickness ranging from about 0.3 microns to about 2.0 microns. Additionally, as indicated at step 105, the patterned photoresist formed on the wafer is baked, i.e., subject to heat treatment, for example at temperatures of approximately 180° C. for a duration of about 2 minutes in order to flow the resist to shape the lens structures.

It is understood that prior to applying the resist to the semiconductor wafer, the wafer may be first cleaned and/or treated to increase the adhesion of semiconductor wafer for resist. This treatment consists of processes well known to those skilled in the art and includes, but is not limited to: mechanical roughening with pumice and vapor blast, chemical roughening with etchants and oxide treatments, and chemical adhesion promoters such as silane coupling agents.

Then, according to the invention, as indicated at step 106, a transmissive TARC layer is applied on top of the formed patterned photoresist layer by spinning, CVD or like processes known in the art. TARC functions as a lens coating for the resist, and, particularly, exhibits a refractive index matched to that of the underlying photoresist real index of refraction. According to the invention, a TARC layer is carefully applied to a ¼ wave thickness at the exposure wavelength so that any light reflected off its surface is exactly a ½ wave (i.e., two ¼ waves) out of phase with the light that transmits through the TARC and reflects back from the photoresist layer up through the TARC and out again. These two waves exactly cancel so the interface disappears and eliminates the thin film interference that causes the above-mentioned effective dose problem. In one embodiment, a JSR NFC 540 (JSR Chemical Co. of Japan) or Aquatar™ (Clariant Corporation) TARC is applied at a thickness of 63 nm at the exposure wavelength of about 365 nm.

FIG. 5 illustrates a graph of microlens spacewidth both with the applied TARC (line 95) and without the applied TARC (line 96) (i.e., no thickness) while varying the thickness of the resist layer to simulate the thickness change at the MZ frame in the edge/corners of the array. It is clearly shown in FIG. 5 how the phase change is exhibited with the TARC layer applied and the resulting tighter process control (decreased “swing curve”) that results.

Returning to FIG. 3B, as shown at step 107, a photoresist mask, such as chrome on glass, is applied having a patterned translucent grid comprising a two-dimensional array of opaque squares or rectangles corresponding to the pixel microlens structure to be printed. After aligning the mask to the correct location, the mask and wafer are exposed to a controlled dose of UV light to transfer the mask image.

Then according to the invention, the structure is exposed to a sub-threshold blanket exposure step 110 under conditions which are effective to thin the resist material in the areas forming gaps in the microlens array structure but are insufficient to totally remove the resist material, i.e., the locations of gaps between pixels are partially developed. By “sub-threshold”, it is meant partially exposing a resist material to UV light energy such that the dose of the UV light energy is effective to thin some areas of the resist but is insufficient to clear the resist under normal development conditions.

Specifically, the resist material is exposed to a partial blanket (sub-threshold) exposure step using a UV exposure tool that operates at energies of from about 0.01 to about 2 Joules/cm² or any range of exposure dosage commensurate with the resist thickness. The dose of UV light energy employed in this step of the present invention is a parameter which must be met in order to thin the resist as mentioned above. In accordance with the method of the present invention, the dose of UV light energy which is employed in the sub-threshold exposure step is applied for about 10 msec to about 130 msec. It is understood that preferred conditions for the sub-threshold exposure step are dependent upon the thickness of the photoresist layer. Example conditions for the lens thicknesses are as follows: UV light energy of from about 0.06 to about 0.2 Joules/cm² at a dosage of from about 45 msec to about 120 msec. It is emphasized that this step of the present invention is carried out under controlled conditions which are not capable of totally removing the resist material in the gaps. Instead, the conditions are such that the only some of the exposed resist regions are removed in the development step to result in a webbing of the lenses together.

It is understood that any wavelength of light within the UV range, e.g. 365 nm (Mid-UV) or 248 nm (Deep-UV), may be employed in the present invention and may be filtered to achieve the proper dose. When a 365 nm UV light energy source is employed, this step of the present invention is carried out at an energy of from about 0.04 to about 2.0 Joules/cm², more preferably from about 0.06 to about 1.0 Joules/cm². When the UV light energy is from a 248 nm light source, the sub-threshold exposure step is carried out at an energy of from about 0.6 to about 1.2 Joules/cm², more preferably about 0.8 to about 1.0 Joules/cm². It is understood that the dosages applied will vary dependent upon lens thickness.

It is further understood that the thinned optically sensitive resist of the present invention obtained by utilizing a sub-threshold exposure step wherein a dose of UV energy effective to thin predetermined areas of the resist but insufficient to clear the resist under normal development conditions is employed, after development, retains its sensitivity to exposure. Therefore, the resist of the present invention can be re-exposed with a pattern mask to achieve imaging at ultra-thin resist conditions.

Then, as shown in FIG. 3B, the sub-threshold exposed structure is developed at step 115 utilizing an organic solvent (hereinafter “developer”) that dissolves the partially exposed areas. Generally, the partially exposed areas of resist are developed by conventional methods which include, but are not limited to: using propylene carbonate, gamma butyrolactone, an ammonium hydroxide such as tetramethyl ammonium hydroxide, diglyme or mixtures thereof. A highly preferred developer employed in the present invention is A2300 MIF (0.263 N) supplied by International Business Machines Corporation which comprises about 2% tetramethyl ammonium hydroxide and 98% water.

An optional step may then be employed to remove the TARC layer topcoat, however, may not be necessary if the developer treatment also removes the top TARC layer topcoat. In one embodiment, for example, a deionized water rinse may be used to remove the TARC prior to development of the photoresist.

As further shown in FIG. 3B, at a next step 118, a further blanket (i.e., bleaching) expose dose is applied to the whole structure (including gaps and lenses) at approximately the same dose as the imaging dose as applied at step 110. It is understood that the flow conditions and bleaching dose must be carefully controlled to effect the rate of cross-linking of the polymeric compounds to achieve a desired thickness of the microlens material in the gap and desired lens shape (i.e., radius of curvature and lens thickness). Preferably, this additional exposure is applied to the formed webbed areas to promote faster polymer cross-linking in these areas.

After the additional post-development exposure or “bleaching” dose to initiate cross-linking the polymer chains in the resist in a desired manner, as indicated at step 120, the flow conditions are applied to melt the photoresist and form the microlens structure. This requires an application of thermal energy (temperature) to convert the raised photoresist islands into semi-spherical convex lenses of circular plan shape. It is understood that a carefully controlled dose is essential due competing conditions relating between flow (needed to melt into lens shape) and the cross-linking reaction that stops the flow. For example, greater dosage increases free radicals that cross-link so double exposed webbed region cross-links first, thus preventing the lenses from webbing together. That is, flow bake conditions are such that the corner areas of the lenses, e.g., at the 45° (degree) cut, are down from the webbed edges so that the radius of curvature can be matched to the cross-section of the lenses at the webbed edges thereby maximizing the light collection. Flow temperatures ranging between 180° C.-220° C., e.g., 210° C., may be applied for a time adequate to ensure adequate rate of cross-linking versus melting rate and ensure complete cross-linking.

FIG. 6 shows an example of a webbed microlens structure 200 formed in accordance with the process of the invention. As shown in FIG. 6, the cross section 225 taken along line A′-A′ of a formed lens 200 includes webbed edges at an ideal radius of curvature R1 according to a desired focal length of the microlens structure; and, according to the invention, the radius of curvature R2 at cross section 230 taken along line B′-B′ and angled at 45 degrees is additionally matched to the cross-section 225. This is due to the fact that due to the carefully controlled additional expose and bake conditions that control the horizontal webbing and effectively enable the corner areas of the lenses, e.g., at the 45° (degree) cut, to be shrunk in the vertical dimension at a distance lower than the webbed edges, e.g., by a distance “d”, such that the radius of curvature can be matched to the cross-section. In the example microlens design shown in FIG. 6, there is approximately a 0.2 μm webbing horizontally with open corners at the 45° cut in the ideal lens structure of this embodiment, resulting in more focused light 255 in the microlens cell structure 200 as compared to the light received at the 45° cut in prior art microlens structures.

Advantageously, according to the methodology of the invention, dimensions of each microlens structure of a pixel or sensor array, including lens size, height and radius of curvature can be controlled for webbed microlens designs having a round shape of the lens in all directions. FIG. 7 shows a graphical depiction 300 of a cross section analysis 90 of an example measurement of a microlens formed according to the method of the invention with a lens width “w” and a height “h” and points depicting the shrinking of the lens at the gaps, with the radius of curvature “R” at this cross-section view governed according to equation (1) as follows: R ² =h ²+(w/2)²/2h  (1)

FIG. 4 depicts a pixel sensor array 10 in which the webbed microlens structure 200 formed in accordance with the invention may be employed. As shown, the array comprises a plurality of microlenses 12, each having a hemisphere or semi-hemishperical shape, arranged on a smooth planarization layer 17, e.g., a spin on polymer, that is formed on top of a filter array, e.g., color filters 15, enabling formation of the microlens array. The color filter array 15 includes individual red, green and blue filter elements 25 (primary color filters) or alternately, cyan, magenta and yellow filter elements (complementary color filter). Each microlens 22 of the microlens array 12 is aligned with a corresponding color filter element 25 and comprises an upper light receiving portion of a pixel 20. The pixel 20 includes a cell portion fabricated upon a semiconductor substrate 14 portion including a stack of comprising one or more interlevel dielectric layers 30 a-30 c incorporating metallization interconnect levels M1, M2 Aluminum Al or Cu wire layers 35 a, 35 b. Interlevel dielectric materials may comprise a polymer or SiO₂, for example. As Al metallization interconnect layers 35 a, 35 b do not require passivation, no respective barrier layers are shown. As further shown in FIG. 4, each pixel cell 20 having the Al metallizations 35 a,b further includes a final Aluminum metal level 36 that enables wire bonding to the M1 and M2 metallizations between each pixel 20, and a final passivation layer 28 is formed above the wire bonding level 36. This final passivation layer 28 may comprise SiN, SiO₂, or combinations of these.

Although not shown in detail, each pixel 20 includes an active photoelectric converting device including a light sensitive element such as a photodiode 18 that performs photoelectric conversion and a CMOS transistor (not shown) that performs charge amplification and switching. Each of the pixels 20 generates a signal charge corresponding to the intensity of light received by each pixel and is converted to a signal current by the photoelectric conversion (photodiode) element 18 formed on semiconductor substrate 14.

FIG. 8 depicts the resulting improvement in lens uniformity 197 at the MZ frame 80 in the edge/corners 70 of the resulting formed pixel array formed in accordance with the process of the present invention.

While there has been shown and described what is considered to be preferred embodiments of the invention, it will, of course, be understood that various modifications and changes in form or detail could readily be made without departing from the spirit of the invention. It is therefore intended that the invention be not limited to the exact forms described and illustrated, but should be constructed to cover all modifications that may fall within the scope of the appended claims. 

1. A method for fabricating a microlens structure in a pixel sensor array comprising the steps of: a. providing a substrate including a plurality of light sensitive elements adapted to receive light incident to a respective pixel microlens; b. forming a single photoresist material layer over said substrate; c. applying an anti-reflective coating layer on top of said single photoresist material layer; d. patterning said single photoresist layer using a first sub-resolution condition to form microlens structure images, said first sub-resolution condition applied in a manner sufficient to form partially connected lens portions at gaps between adjacent microlens structures; e. developing said single photoresist layer to partially form the patterned microlens structures having partially connected lens portions at said gaps; f. blanket applying a second sub-resolution condition to the partially formed microlens structures; and g. thermally reflowing said partially formed microlens structures, wherein each microlens structure is webbed such that said microlens structure touches a microlens structure of an adjacent pixel in said array, wherein said thermally reflowing increases a curvature of said microlens structure to be uniform in all directions to thereby maximize collection of light incident to the microlens structure from all directions, said microlens structure of each microlens having a curvature uniformity exhibited at all pixel locations including those at a pixel array edge or corner.
 2. The method as claimed in claim 1, wherein said first and second sub-resolution conditions comprise a light exposure dose applied to said patterned photoresist layer to initiate cross-linking of polymers of said photoresist material.
 3. The method as claimed in claim 2, wherein said patterning step c), comprises applying said first sub-resolution condition to a mask image that ensures polymer cross-linking at gaps located between adjacent cells at a horizontal cross section.
 4. The method as claimed in claim 2, wherein said first and second sub-resolution conditions comprises an exposure dose of UV light at energies ranging from about 0.01 to about 2 Joules/cm².
 5. The method as claimed in claim 1, wherein said reflowing step f) comprises a post-exposure bake process for applying heat to said microlens structures at a temperature ranging from about 180° C. to about 220° C.
 6. The method as claimed in claim 1, wherein each said touching microlens structure is of circular plan shape formed to have a matched uniform radius of curvature at a horizontal cross-section and at a 45 degree cross-section.
 7. The method as claimed in claim 6, wherein said touching microlens structure at said 45 degree cross-section is formed at a lower vertical distance below a horizontal where the webbed edges touch at said horizontal cross-section so that the radius of curvature of the microlens can be matched to the radius of curvature of the microlens at the horizontal cross-section.
 8. The method as claimed in claim 1, wherein said anti-reflective coating layer applied on top of said photoresist material layer is of sufficient thickness to tighten process control conditions at or near said pixel array edge or corner.
 9. A method of controlling dimensions of a formed microlens structure of a sensor array, said dimensions including a lens size, height and radius of curvature, said method comprising: applying first exposure conditions to a single photoresist layer having an anti-reflective coating layer applied thereon, said single photoresist layer patterned to partially form touching microlens structures and developing said layer after first dose exposure; blanket applying second exposure conditions to said partially formed touching microlens structures of said array; and thermally reflowing said partially formed touching microlens structures of said array at temperatures sufficient to increase curvature of said microlens structures and form adjacent microlens structures having a round lens shape in all directions.
 10. The method as claimed in claim 9, wherein each said touching microlens structure is formed to have a matched uniform radius of curvature at a horizontal cross-section and at a 45 degree cross-section.
 11. The method as claimed in claim 9, wherein said thermally reflowing step is conducted at a temperature sufficient to ensure shrinkage of each said touching microlens structure at said 45 degree cross-section such that the radius of curvature of the microlens at the 45 degree cross-section can be matched to the radius of curvature of the microlens at the horizontal cross-section.
 12. The method as claimed in claim 11, wherein said blanket applying second exposure conditions and said thermally reflowing steps are conducted to ensure shrinkage of each said touching microlens structure at said 45 degree cross-section at a lower vertical distance below a horizontal where the lens edges touch at said horizontal cross-section.
 13. The method as claimed in claim 9, wherein each said touching microlens structure is formed to have a lens width “w” and a height “h” and a radius of curvature “R” at any cross-section governed according to R²=h²+(w/2)²/2h. 